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Inferior Vena Cava Compliance in Trans-thoracic Echocardiography: is the Trans-hepatic Window as Reliable as the Subcostal One

Sponsor
Brugmann University Hospital (Other)
Overall Status
Completed
CT.gov ID
NCT04866095
Collaborator
(none)
53
Enrollment
1
Location
1
Arm
4.5
Actual Duration (Months)
11.8
Patients Per Site Per Month

Study Details

Study Description

Brief Summary

The ability to assess intravascular volume is an essential part of perioperative care:

insufficient intravascular volume can result in decreased oxygen delivery to tissues and organ dysfunction, while fluid overload can contribute to the development of oedema, organ dysfunction, respiratory failure and healing defect.

At the present state, there are many different methods of interpreting intravascular circulating blood volume. Non-invasive techniques such as the Clear Sight System, and the transthoracic echocardiogram (TTE) have been proposed as non-invasive methods to assess patient' blood volume.

The aim of this study is to assess whether the measure of the inferior vena cava (IVC) in the trans-hepatic window is as reliable as in the subcostal window to determine fluid responsiveness in perioperative patients. In this study, preload increase will be obtained through passive leg raising. Sensibility and specificity of the two echocardiographic approaches to predict fluid responsiveness will be compared while using the subcostal window as the "gold standard". The effect of passive leg elevation on patient's cardiac output response will be assessed with two different non-invasive techniques: the Clear Sight system and the TTE.

Condition or Disease Intervention/Treatment Phase
  • Device: Transthoracic echocardiogram
  • Device: Clear Sight system
 N/A

Detailed Description

The ability to assess intravascular volume is an essential part of perioperative care:

insufficient intravascular volume can result in decreased oxygen delivery to tissues and organ dysfunction, while fluid overload can contribute to the development of oedema, organ dysfunction, respiratory failure and healing defect.

Assessment of the volume status in perioperative patients relies on two important concepts:

euvolemia and fluid responsiveness.

Euvolemia describes a state of adequate circulating blood volume that allows suitable filling of the cardiac chambers making possible for the heart to produce a cardiac output that meets the peripheral oxygen demand.

Fluid responsiveness describes the ability of the heart to adapt blood flow in response to preload increase.

As euvolemia is the ultimate goal of fluid administration then evaluating fluid responsiveness reflects the process of working toward establishing euvolemia.

At the present state, there are many different methods of interpreting intravascular circulating blood volume: those related to pressures measurements: the central venous pressure (CVP), the pulmonary artery occluded pressure (PAOP), and those related to cardiac output measurements like thermodilution and pulse contour techniques. It is worth noting that all these are invasive methods that expose patients to a series of possible side effects such as: pneumothorax, infections, hematomas and vascular lesions. Non-invasive techniques such as the Clear Sight System, and the transthoracic echocardiogram (TTE) have been proposed as non-invasive methods to assess patient' blood volume.

TTE is a widely used and validated imaging technique which involves the study of the heart and great vessels through multiple examination windows.

In particular, the subcostal window represents the gold standard for evaluating the diameter of the inferior vena cava (IVC) and its compliance, allowing the physician to obtain valuable information on the volume status of patients: several studies have reported that these measurements could predict accurately the hemodynamic response of patient to a change in cardiac preload. However, acquiring images in the subcostal window can be, in some cases, difficult or impossible due to the presence of drainages or surgical wounds; in such cases an alternative could be represented by the trans-hepatic window which, at the best of the investigator's knowledge, it has never been validated in the literature.

The Clear Sight System is a non-invasive blood pressure (BP) monitoring system, where the CO is determined analysing the photo-plethysmography curve by a miniaturized pressure cuff and infrared LEDs.

Its main advantage is to assess CO continuously in a completely non-invasive way, following its variations and thereby contributing to the detection of hypovolaemia. Other visualized parameters are: the stroke volume (SV), the systemic vascular resistance (SVR) as well as the BP and the heart rate (HR).

Passive leg raising (PLR) is a test developed to predict patient's hemodynamic response to increase preload without any fluid administration. Raising the patient from a semi-recumbent position to a position with the head at 0° and the legs raised to a 45° angle is associated with about 300 ml of blood volume mobilization from the lower limbs and splanchnic territory to the central compartment resulting in increased venous return to the heart. This manoeuvre provokes a preload increase to which patients could respond with (responder) or without (non-responders) an augmentation of their cardiac output.

The aim of this study is to assess whether the measure of the IVC in the trans-hepatic window is as reliable as in the subcostal window to determine fluid responsiveness in perioperative patients. In this study, preload increase will be obtained through passive leg raising. Sensibility and specificity of the two echocardiographic approaches to predict fluid responsiveness will be compared while using the subcostal window as the "gold standard". The effect of passive leg elevation on patient's cardiac output response will be assessed with two different non-invasive techniques: the Clear Sight system and the TTE.

Study Design

Study Type:
Interventional
Actual Enrollment :
53 participants
Allocation:
N/A
Intervention Model:
Single Group Assignment
Masking:
None (Open Label)
Primary Purpose:
Diagnostic
Official Title:
Inferior Vena Cava Compliance in Trans-thoracic Echocardiography: is the Trans-hepatic Window as Reliable as the Subcostal One
Actual Study Start Date :
Jun 25, 2021
Actual Primary Completion Date :
Oct 30, 2021
Actual Study Completion Date :
Nov 9, 2021

Arms and Interventions

Arm Intervention/Treatment
Experimental: Surgery

All patients, who have given their consent, aged over 18 years, with a sinus rhythm, requiring a surgical procedure that allows obtaining high quality transthoracic echocardiogram imaging without pain and discomfort.

Device: Transthoracic echocardiogram
Transthoracic echocardiogram (TTE) is a widely used and validated imaging technique which involves the study of the heart and great vessels through multiple examination windows. In particular, the subcostal window represents the gold standard for evaluating the diameter of the inferior vena cava (IVC) and its compliance, allowing the physician to obtain valuable information on the volume status of patients. Acquiring images in the subcostal window with a transthoracic echocardiogram (TTE) can be, in some cases, difficult or impossible due to the presence of drainages or surgical wounds: in such cases an alternative could be represented by the trans-hepatic window. This has not been validated in the scientific litterature.

Device: Clear Sight system
The Clear Sight System is a non-invasive blood pressure (BP) monitoring system, where the CO is determined analysing the photo-plethysmography curve by a miniaturized pressure cuff and infrared LEDs. Its main advantage is to assess CO continuously in a completely non-invasive way, following its variations and thereby contributing to the detection of hypovolaemia. Other visualized parameters are: the stroke volume (SV), the systemic vascular resistance (SVR) as well as the BP and the heart rate (HR).

Outcome Measures

Primary Outcome Measures

  1. Difference of sensitivity between the trans-hepatic window versus the subcostal window with TTE [20 minutes]

    Comparison of the sensitivity of both the trans-hepatic window and the subcostal window to predict the cardiac output response by transthoracic echocardiogram (TTE) to passive leg raising.

  2. Difference of specificity between the trans-hepatic window versus the subcostal window with TTE [20 minutes]

    Comparison of the specificity of both the trans-hepatic window and the subcostal window to predict the cardiac output response by transthoracic echocardiogram (TTE) to passive leg raising.

Secondary Outcome Measures

  1. Difference of sensitivity between the trans-hepatic window versus the subcostal window with the Clear Sight system [20 minutes]

    Comparison of the sensitivity and specificity of both the trans-hepatic window and the subcostal window to predict the cardiac output response (with the Clear Sight system) to passive leg raising.

  2. Difference of specificity between the trans-hepatic window versus the subcostal window with the Clear Sight system [20 minutes]

    Comparison of the sensitivity and specificity of both the trans-hepatic window and the subcostal window to predict the cardiac output response (with the Clear Sight system) to passive leg raising.

  3. Right atrial pressure (RA)- trans-hepatic window [20 minutes]

    Evaluation of the estimation of RA pressure obtained with the trans-hepatic and sub-costal approaches

  4. Right atrial pressure (RA) - subcostal window [20 minutes]

    Evaluation of the estimation of RA pressure obtained with the trans-hepatic and sub-costal approaches

  5. Cardiac output [20 minutes]

    Cardiac output calculated by: CO= sub-Aortic Velocity Time Integral (sAoVTI) × heart rate in beats per minute (bpm) × left ventricular outflow track (LVOT)

Eligibility Criteria

Criteria

Ages Eligible for Study:
18 Years and Older
Sexes Eligible for Study:
All
Accepts Healthy Volunteers:
No
Inclusion Criteria:

All patients of the CHU Brugmann hospital, who have given their consent, aged over 18 years, with a sinus rhythm, requiring a surgical procedure that allows obtaining high quality TTE imaging without pain and discomfort.

Examples of such surgeries are:

  • Orthopaedic surgery: interventions of upper limbs.

  • Stomatology: dental extractions

  • Gastroenterology: oesophagus gastroscopy

  • Maxillo-facial surgery: septoplasties, rhinoplasties, Le Fort surgeries

  • ENT surgery: thyroidectomy, sleep endoscopies

  • Gynaecology: hysteroscopy, voluntary terminations of pregnancy

  • Ophthalmic surgery

Exclusion Criteria:

  • Refusal to participate to the study

  • suboptimal image acquisition

  • atrial fibrillation, patients with 6 or more extra systoles per minute

  • cardiac valvular pathologies

  • TTE imaging causing pain and/or discomfort to the patient

  • surgeries that don't allow obtaining high quality imaging, elevated intra-abdominal pressure.

Contacts and Locations

Locations

Site City State Country Postal Code
1 CHU Brugmann Brussels Belgium 1020

Sponsors and Collaborators

  • Brugmann University Hospital

Investigators

  • Principal Investigator: Francesco Zuccarini, CHU Brugmann

Study Documents (Full-Text)

None provided.

More Information

Publications

None provided.
Responsible Party:
Denis SCHMARTZ, Head of anesthesiology department, Brugmann University Hospital
ClinicalTrials.gov Identifier:
NCT04866095
Other Study ID Numbers:
  • CHUB-WICAVE
First Posted:
Apr 29, 2021
Last Update Posted:
Nov 10, 2021
Last Verified:
Nov 1, 2021
Individual Participant Data (IPD) Sharing Statement:
No
Plan to Share IPD:
No
Studies a U.S. FDA-regulated Drug Product:
No
Studies a U.S. FDA-regulated Device Product:
No

Study Results

No Results Posted as of Nov 10, 2021